JP5773584B2 - Printing apparatus and ink supply method thereof - Google Patents

Description

  The present invention relates to a printing apparatus (recording apparatus) that prints an image by discharging ink from a print head (recording head) onto a sheet, and an ink supply method thereof. More specifically, the present invention relates to a printing apparatus that prints an image on a sheet using ink in which ink components easily settle, and an ink supply method thereof.

  Patent Document 1 describes that a valve unit that opens and closes an ink supply path is disposed between an ink cartridge and a recording head, and the suction pump is driven with the valve unit closed. Further, it is described that the valve unit is opened in a state where negative pressure is accumulated in the internal space of the capping means, and a fast ink flow is generated in the ink flow path from the ink cartridge to the nozzle opening of the recording head. Accordingly, it is described that bubbles that remain stuck in the ink flow path can be peeled off from the ink flow path. In such a state where the valve provided in the middle of the ink supply path is closed, the recording head side is depressurized from the valve of the ink supply path, and the valve is opened in a state where negative pressure is accumulated, so that ink is supplied to the recording head. The method of supplying is hereinafter referred to as “choke suction”.

JP 2001-113726 A

  Patent Document 1 describes black, cyan, magenta, and yellow as inks. However, there is no description of the ink components.

  Here, in a printer that uses ink in which the ink components are likely to settle, it is necessary to agitate the ink to homogenize the ink concentration. As a configuration for stirring the ink, there is a configuration in which the ink pack is mounted on the recording apparatus after the user has stirred the ink in the ink pack by operating the operated portion. If the above-described choke suction is performed by a printer that uses ink that easily causes the ink components to settle, the user must operate the operated portion to stir the ink, and then perform choke suction to supply the ink to the recording head. I must. Therefore, chalk suction is performed after stirring, and there is a problem that it takes a long time until the recording apparatus is ready for use.

  In view of such circumstances, an object of the present invention is to provide a printing apparatus and an ink supply method thereof that can reduce the time required for the ink agitation operation and the ink supply operation to the print head.

In order to achieve the above object, the present invention provides a print head that ejects ink, an ink tank that stores ink to be supplied to the print head, an agitation unit that agitates ink in the ink tank, and the ink tank. Pressurizing means for pressurizing, a supply path for supplying ink from the ink tank to the print head, a valve provided in the supply path, and a suction means for sucking ink from the print head in printing apparatus comprising, said suction means is driven in after driving said stirring means to close the valve, then a control means for driving said pressurizing means while by driving the agitation means, wherein the print head side ink from the ink tank opens the valve in a state in which negative pressure is accumulated into the print head, characterized in Rukoto supplied to.

  Time required for stirring and ink supply because the stirring operation for stirring the ink in the ink containing bag by the stirring means and the pressure reducing operation for reducing the pressure on the print head side from the valve in the supply path by the pressure reducing means are performed in parallel. Can be shortened.

  According to the present invention, it is possible to provide a printing apparatus and an ink supply method thereof that can shorten the time required for the ink stirring operation and the ink supply operation to the print head.

1 is a perspective view of a printing apparatus to which the present invention can be applied. It is a figure explaining the ink tank concerning this invention. It is a perspective view explaining the structure which an ink tank engages with an ink tank holder. FIG. 3 is a schematic diagram illustrating a configuration for supplying ink from an ink tank to a print head. It is a block diagram of a control part. It is a flowchart explaining operation | movement of chalk suction. It is a flowchart explaining the ink supply operation | movement of this embodiment. It is a figure explaining the timing of the ink supply operation | movement of this embodiment.

(First embodiment)
The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 1 is a perspective view of a printing apparatus to which the present invention can be applied. In FIG. 1, reference numeral 101 denotes an ink tank that stores ink. Ink tanks for storing yellow ink, magenta ink, cyan ink, and black ink are provided. An ink tank holder 102 is arranged so that a plurality of ink tanks 101 can be mounted.

  Reference numeral 103 denotes a carriage that moves by mounting a print head (recording head) (not shown). The print head performs recording by ejecting ink onto the recording medium P. A carriage 103 (not shown) and a sub tank 104 that stores ink to be supplied to the print head are mounted on the carriage 103. The ink tank 101 and the sub tank 104 are connected by an ink supply tube 105. The ink stored in the ink tank 101 is supplied to the sub tank 104 via the ink supply tube 105.

  Reference numeral 106 denotes a conveyance roller that conveys the recording medium P in a direction crossing the moving direction of the carriage 103. Reference numeral 107 denotes a recovery unit that is disposed outside the area where the recording medium P is conveyed and performs a recovery operation of the print head (recording head). The recovery unit 107 includes a cap for capping the ejection port surface of the print head, a wiper for wiping the ejection port surface, and a pump for sucking ink from the print head.

  FIG. 2 is a diagram illustrating the ink tank 101 according to the present invention. 2A is a perspective view of the ink tank 101, and FIG. 2B is a cross-sectional view of the ink tank 101. In FIG. 2, an ink containing bag 110 is provided inside the ink tank 101. The ink containing bag 110 is formed by joining two films, and contains ink in which a printing pigment is dispersed in a solvent. In the present invention, the ink in the ink containing bag is described as being a pigment ink, but the same effect can be obtained regardless of whether it is a dye ink or a treatment liquid. The present invention has a specific effect in a configuration using an ink in which ink components are settled. An ink supply unit 111 protrudes from the end of the ink storage bag 110 so as to be partially exposed, and the ink in the ink storage bag is taken out from the ink supply unit 111. That is, ink is supplied from the ink supply unit 111 to the sub tank 104 via the ink supply tube 105.

  Reference numeral 112 denotes a stirring member. The stirrer 112 includes a stirrer 112a that stirs ink, a flexible elastic part 112b, a joint 112c that joins the film of the ink containing bag 110, and a drive input part 112d that protrudes outside the ink tank 101. And comprising. As will be described later, when the drive input portion 112d is swung, the agitating portion 112a is swung around the joining portion 112c, and the ink in the ink containing bag 110 is agitated. As the agitation unit 112a swings, the pigment component that has settled in the ink containing bag 110 can be agitated, and unevenness in ink density can be eliminated.

  FIG. 3 is a perspective view illustrating a configuration in which the drive input unit 112 d of the ink tank 101 is engaged with the ink tank holder 102. When the ink tank 101 is mounted on the liquid ejection apparatus main body, the ink tank 101 is inserted from an opening provided on the front side of the ink tank holder 102. The mounting portion for mounting each ink tank 101 of the ink tank holder 102 is provided with an engaging portion 120 that can be engaged with the drive input portion 112 d of the ink tank 101. In FIG. 3, reference numeral 130 denotes a drive unit that engages with the drive input unit 112 d of the ink tank 101 when the ink tank 101 is completely attached to the ink tank holder 102. When the drive unit is driven in a state where the drive input unit 112d of the ink tank 101 is engaged with the drive unit, the drive input unit 112d is swung. When the drive input unit 112d swings, the stirring unit 112a swings accordingly, and the ink in the ink containing bag 110 can be stirred.

  FIG. 4 is a schematic diagram illustrating a configuration for supplying ink from the ink tank 101 to the print head. Reference numeral 130 denotes a pressurizing pump as a driving means. By driving the pressurizing pump 130, the drive input portion 112d of the stirring member 112 is swung. As the drive input unit 112d is swung, the stirring unit 112a is swung, and the ink in the ink containing bag 110 is stirred. The pressurization pump 130 is a diaphragm pump in this embodiment, and uses a motor as a drive source. When the pressure pump 130 rotates forward, the driven part 112d of the stirring member 112 is driven, and the ink tank 101 is stirred. When the pressure pump 130 is reversed, the drive is not transmitted to the stirring member 112 and the stirring operation of the ink tank 101 is not performed.

  A solenoid valve 140 connects the ink tank 101 and the pressurizing pump 130. The pressurizing pump 130 sends air for pressurizing the ink containing bag. The solenoid valve 140 switches between open and closed states by turning on and off the power. When the solenoid valve 140 is open, the pressurizing pump 130 and the inside of the ink tank 101 communicate with each other. When the pressurizing pump 130 rotates normally or reverses with the solenoid valve 140 open, the inside of the ink tank 101 is pressurized. That is, the solenoid valve 140 functions as a switching member that switches whether to introduce the air sent from the pressure pump 130 into the ink tank 101. When the inside of the ink tank 101 is pressurized, the ink containing bag 110 is crushed and ink can be supplied from the ink tank 101 to the print head via the ink supply tube 105. That is, when the pressure pump 130 rotates forward with the solenoid valve 140 open, the ink storage bag 110 of the ink tank 101 is pressurized and the ink in the ink storage bag 110 is agitated. In addition, when the pressurizing pump 130 rotates forward with the solenoid valve 140 closed, the ink in the ink containing bag 110 is agitated. At this time, the ink containing bag 110 is not pressurized. In this embodiment, the stirring member 112 is driven by the pressurizing pump 130 that sends air for pressurizing the ink containing bag 110. However, the stirring member 112 may be driven by another drive source.

  Reference numeral 150 denotes a differential pressure valve provided in the middle of the ink supply tube 105. The differential pressure valve 150 is opened when the pressure on the upstream side (ink tank 101 side) of the differential pressure valve is higher than the pressure on the downstream side (print head side) of the differential pressure valve by a predetermined amount or more.

  Reference numeral 160 denotes a cap capable of coming into contact with the discharge port surface of the print head. Reference numeral 170 denotes a suction pump as decompression means (negative pressure generation means) connected to the cap 160. By driving the suction pump 170, a negative pressure can be generated in the cap. By generating a negative pressure in the cap, it is possible to discharge thickened ink and bubbles from the print head, or supply ink from the ink tank 101 to the print head.

  Next, choke suction will be described. If there is a certain amount or more of bubbles or thickened ink in the ink supply path, ink supply to the nozzles of the print head may be hindered and ejection failure may occur. As a method of preventing this ejection failure, choke suction that discharges bubbles and thickened ink in the ink supply path by an ink flow having a high flow velocity is effectively used. In this choke suction, the pressure on the print head side may be reduced from the ink supply path valve, and the ink cartridge side may be pressurized from the ink supply path valve.

  A basic configuration of choke suction in the present embodiment will be described. A differential pressure valve is provided in the ink supply path from the ink tank to the print head. Ink is supplied by the difference between the pressure on the ink tank side from the differential pressure valve in the ink supply path and the pressure on the print head side from the differential pressure valve in the ink supply path.

  FIG. 5 is a block diagram illustrating the concept of the control unit. A controller included in the control unit (a range surrounded by a broken line) includes a CPU 201, a ROM 202, a RAM 203, an HDD 204, an image processing unit 207, an engine control unit 208, and an individual unit control unit 209. A CPU (central processing unit) 201 controls the operation of each unit of the printing apparatus in an integrated manner. The ROM 202 stores programs to be executed by the CPU 201 and fixed data necessary for various operations of the printing apparatus. The RAM 203 is used as a work area for the CPU 201, used as a temporary storage area for various received data, and stores various setting data. An HDD (hard disk) 204 can store and read programs to be executed by the CPU 201, print data, and setting information necessary for various operations of the printing apparatus. The operation unit 15 is an input / output interface with a user, and includes an input unit such as a hard key and a touch panel, and an output unit such as a display for presenting information and a sound generator. For example, a display with a touch panel is used, and the operation status, printing status, maintenance information (remaining ink amount, remaining sheet amount, maintenance status, etc.) of the apparatus are displayed to the user. The user can input various information from the touch panel.

  A dedicated processing unit is provided for units that require high-speed data processing. An image processing unit 207 performs image processing of print data handled by the printing apparatus. The color space (for example, YCbCr) of the input image data is converted into a standard RGB color space (for example, sRGB). Various image processing such as resolution conversion, image analysis, and image correction is performed on the image data as necessary. Print data obtained by such image processing is stored in the RAM 203 or the HDD 204. The engine control unit 208 also performs drive control of the print head according to print data based on a control command received from the CPU 201 or the like. The individual unit control unit 209 is a sub-controller for individually controlling each unit of the pressurizing pump 130, the solenoid valve 140, the cap 160, and the suction pump 170. The individual unit control unit 209 controls the operation of each unit based on a command from the CPU 201. The external interface 205 is an interface (I / F) for connecting the controller to the host device 16, and is a local I / F or a network I / F. The above components are connected by the system bus 210.

  The host device is a device serving as a supply source of image data for causing the printing device to perform printing. The host device may be a general-purpose or dedicated computer, or may be a dedicated image device such as an image capture having an image reader unit, a digital camera, or a photo storage. When the host device is a computer, an OS, application software for generating image data, and a print driver for the printing device are installed in a storage device included in the computer. Note that it is not essential to implement all of the above processing by software, and part or all of the processing may be realized by hardware.

  FIG. 6 is a flowchart for explaining the choke suction operation. In step S101, the driving of the pressure pump 130 is stopped. By stopping the driving of the pressure pump 130, the pressure state in the ink supply path is released. In step S102, driving of the suction pump 170 is started. By driving the suction pump 170, the pressure in the ink supply path decreases. When the pressure in the ink supply path becomes lower than the predetermined pressure, the opened differential pressure valve 150 is closed in step S103. Specifically, the upstream and downstream sides of the ink supply path are blocked by the movement of the valve member to close the ink supply path. The suction pump 170 continues to be driven even after the differential pressure valve 150 is closed. By continuing to drive the suction pump 170, the absolute value of the negative pressure in the ink supply path downstream of the differential pressure valve 150 increases.

  In step S104, the driving of the pressurizing pump 130 is started after a predetermined time has elapsed since the driving of the suction pump 170 was started. By driving the pressure pump 130, the pressure in the ink supply path on the ink tank side (upstream side) of the differential pressure valve 150 is increased. When the pressure on the upstream side of the differential pressure valve 150 becomes higher than the pressure on the print head side (downstream side) of the differential pressure valve 150 by a predetermined amount or more, the closed differential pressure valve 150 is opened in step S105. Specifically, the valve member is in a position where the ink supply path is blocked by the negative pressure on the downstream side of the ink supply path. As the pressure on the upstream side of the ink supply path increases, the valve member moves against the negative pressure on the downstream side to open the ink supply path.

  When the differential pressure valve 150 is opened, in step S106, ink is supplied from the ink tank 101 to the print head due to the pressure difference between the upstream side and the downstream side.

  Choke suction is mainly necessary in the following cases. The first case is when the printing apparatus has not been used for a long time. If the printing apparatus has not been used for a long period of time, thickened ink and air bubbles may remain in the ink supply path, which may cause a print head ejection failure.

  The second case is when a long time has passed since the ink supply path was filled with ink. In this case as well, thickened ink and air bubbles may remain in the ink supply path, and the print head may fail to discharge. Here, the long term in the first case and the second case is about 1.5 months.

  The third case is when a new ink tank is installed in the printing apparatus. This is because a small amount of air bubbles enter the ink supply path when a new ink tank is attached to the printing apparatus. In consideration of the number of times the ink tank has been replaced and the like, when it is considered that a predetermined amount or more of bubbles are staying in the ink supply path, choke suction is performed.

  Here, when performing chalk suction, it is desirable that the ink concentration in the ink tank be uniform. This is because when the pigment ink is used, if the pigment component is settled, the ink in which the pigment component is precipitated is supplied to the print head. In the three cases where the above-described choke suction is required, there is a high possibility that the pigment component has settled in the ink tank.

  Therefore, when performing chalk suction, it is desirable to eliminate the settled state of the pigment component in the ink tank by stirring operation before performing chalk suction. In such a case, in the conventional configuration, the chalk suction is executed after the pigment component in the ink tank is stirred by the stirring means. For this reason, the user of the printing apparatus waits for the time necessary for performing the chalk suction in addition to the stirring time necessary for eliminating the sedimentation of the pigment component.

  Here, the stirring time required to eliminate the precipitation of the pigment component is determined as follows, for example. First, the patch is recorded with a well-stirred and homogeneous ink, and then the ink with the pigment component settling is stirred for N seconds. These patches are color-measured to obtain the color difference ΔE. Shaking time is varied, patch recording and color difference ΔE are measured, and the relationship between stirring time and color difference ΔE is obtained. From this relationship, it is possible to determine the necessary agitation time for suppressing the color difference ΔE with the homogeneous ink to a predetermined value or less.

  FIG. 7 is a flowchart for explaining the ink supply operation of the present embodiment. FIG. 8 is a diagram illustrating the timing of the ink supply operation of the present embodiment.

  In step S201 in FIG. 7, the driving of the pressure pump 130 is stopped. The timing for stopping the driving of the pressure pump 130 is T0 in FIG. By stopping the driving of the pressure pump 130, the pressure state in the ink supply path is released. In step S202, the solenoid valve 140 is closed and the pressure pump 130 is rotated in the forward direction to swing the stirring member 112 to stir the ink in the ink containing bag 110.

  After a lapse of a predetermined time from the start of the ink stirring operation, the suction pump 170 starts to be driven in step S203. The timing to start driving the suction pump 170 is T1 in FIG. By starting the driving of the suction pump 170, the pressure in the ink supply path decreases. Here, the stirring operation in the ink tank 101 can be performed in parallel with the operation of depressurizing the ink supply path by the suction pump 170. When the pressure in the ink supply path becomes lower than the predetermined pressure, the opened differential pressure valve 150 is closed in step S204. The suction pump 170 continues to be driven even after the differential pressure valve 150 is closed. By continuing to drive the suction pump 170, the absolute value of the negative pressure in the ink supply path downstream of the differential pressure valve 150 increases.

  In step S205, the solenoid valve 140 is opened while the pressure pump 130 is driven to swing the stirring member 112 and pressurize the ink containing bag 110. The timing for opening the solenoid valve 140 is T2 in FIG. By driving the pressure pump 130, the pressure in the ink supply path upstream of the differential pressure valve 150 is increased. At this time, the driving of the suction pump 170 is continued. When the pressure on the upstream side of the differential pressure valve 150 becomes higher than the pressure on the downstream side of the differential pressure valve 150 by driving the suction pump 170 and the pressure pump 130, the differential pressure valve 150 that has been closed in step S206. Is opened.

  When the differential pressure valve 150 is opened, in step S207, ink is supplied from the ink tank 101 to the print head due to the pressure difference between the upstream side and the downstream side. After a predetermined time has elapsed, the driving of the suction pump 170 is stopped. The timing for stopping the driving of the suction pump 170 is T3 in FIG. Further, after a predetermined time has elapsed, the driving of the pressure pump 130 is stopped and the operation is ended. The timing for stopping the driving of the pressure pump 130 is T4 in FIG. By stopping the driving of the pressurizing pump 130, the stirring operation and the pressurizing operation are completed.

  In the present embodiment, the agitation process can be performed in parallel with the decompression process by the suction pump 170 or the pressurization process by the pressurization pump 130, and therefore, it is necessary to supply ink from the ink tank 101 to the print head. Time can be shortened. In the agitation + pressure process in which the agitation operation and the pressure operation are performed in parallel, the ink in the ink tank 101 is pressurized and supplied into the ink supply path at a high speed while being agitated. At this time, the downstream side of the ink supply path is sufficiently decompressed by driving the suction pump 170. Therefore, due to the pressure difference between the upstream and downstream, the ink in the ink tank 101 moves to the print head at a high speed immediately after the differential pressure valve 150 is opened. The ink that moves at this time stirs the surrounding ink, and the ink itself is also stirred by the surrounding ink. Since the ink is agitated when the differential pressure valve 150 is opened and the ink moves, the agitation time in the ink containing bag can be reduced.

  In the present embodiment, the configuration in which the differential pressure valve 150 automatically opens due to the difference between the pressure upstream of the differential pressure valve 150 in the ink supply path and the pressure downstream of the differential pressure valve 150 has been described. However, the valve provided in the ink supply path may be configured to be opened and closed by a drive source. As long as the valve is opened and closed by the drive source, the configuration may be such that the downstream side of the valve remains at atmospheric pressure and the pressure on the upstream side of the valve is increased. The upstream side of the valve may remain at atmospheric pressure, and the pressure on the downstream side of the valve may be reduced.

  Conventionally, stirring in the ink containing bag took about 120 seconds, but in this embodiment, it could be about 75 seconds. Conventionally, after the agitation operation is performed, the suction pump is driven to depressurize the ink supply path, so that it takes about 60 seconds for the chalk suction. In this embodiment, since the pressurizing operation of the ink containing bag and the driving of the suction pump are performed during the stirring operation, the operation of the stirring + pressurizing step can be performed for about 15 seconds. Therefore, the operation that conventionally took 180 seconds for stirring and chalk suction could be 90 seconds in this embodiment.

(Second Embodiment)
In the first embodiment, the time required for stirring could be shortened by increasing the stirring effect in the stirring + pressure step. In order to further increase the stirring effect, an ink supply path between the ink tank and the sub tank may be provided with a mechanism serving as an ink storage chamber or flow resistance. A similar mechanism may be provided in the ink tank. By providing these mechanisms, the ink flow effect in the ink supply path in the agitation + pressure process is enhanced. Thereby, the stirring time of a stirring + pressurization process can be shortened.

101 Ink tank 105 Ink supply tube 112 Stirring member 150 Differential pressure valve 160 Cap 170 Suction pump

Claims (5)

Print head for ejecting ink, ink tank for storing ink supplied to the print head, agitation means for agitating ink in the ink tank, pressure means for pressurizing the ink tank, and ink tank In a printing apparatus comprising: a supply path for supplying ink from the print head to the print head; a valve provided in the supply path; and suction means for sucking ink from the print head.
After the agitation means is driven, the suction means is driven to close the valve, and thereafter the pressure means is driven while the agitation means is driven, and a negative pressure is applied to the print head side. The printing apparatus, wherein the valve is opened in an accumulated state, and ink is supplied from the ink tank to the print head.   An ink containing bag disposed in the ink tank for containing ink, wherein the pressurizing means sends a pressure pump for pressurizing the ink containing bag; and the air sent by the pressure pump The printing apparatus according to claim 1, further comprising: a switching member that switches whether to introduce the ink into the ink tank. 3. The print according to claim 1, wherein the valve is a differential pressure valve that opens and closes according to a difference between a pressure on the ink tank side and a pressure on the print head side from the valve in the supply path. apparatus. The printing apparatus according to claim 1, further comprising a drive source that opens and closes the valve, wherein the control unit opens the valve by driving the drive source. Print head for discharging ink, ink tank for storing ink to be supplied to the print head, supply path for supplying ink from the ink tank to the print head, and a valve provided in the supply path In an ink suction method in a printing apparatus comprising:
A first step of driving a suction means for sucking ink from the print head after driving a stirring means for stirring the ink in the ink tank and closing the valve;
After the first step, a second step of pressurizing the ink tank while driving the stirring means;
A third step in which, after the second step, the valve is opened in a state where negative pressure is accumulated on the print head side, and ink is supplied from the ink tank to the print head;
An ink supply method comprising:

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